Drosophila Maternal Hsp83 mRNA Destabilization Is Directed by Multiple SMAUG Recognition Elements in the Open Reading Frame▿ †
Autor: | Heli K. Vari, Ramona L. Cooperstock, Craig A. Smibert, Hua Luo, Jennifer L. Semotok, Angelo Karaiskakis, Howard D. Lipshitz |
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Jazyk: | angličtina |
Rok vydání: | 2008 |
Předmět: |
Untranslated region
MRNA destabilization RNA Stability RNA-binding protein Computational biology Biology Open Reading Frames stomatognathic system Protein biosynthesis Animals Drosophila Proteins Transgenes Molecular Biology Heat-Shock Proteins Genetics Messenger RNA Errata Base Sequence RNA-Binding Proteins Translation (biology) Cell Biology Articles Repressor Proteins Open reading frame RNA Messenger Stored Drosophila melanogaster Protein Biosynthesis Mutation Female Smaug |
Popis: | SMAUG (SMG) is an RNA-binding protein that functions as a key component of a transcript degradation pathway that eliminates maternal mRNAs in the bulk cytoplasm of activated Drosophila melanogaster eggs. We previously showed that SMG destabilizes maternal Hsp83 mRNA by recruiting the CCR4-NOT deadenylase to trigger decay; however, the cis-acting elements through which this was accomplished were unknown. Here we show that Hsp83 transcript degradation is regulated by a major element, the Hsp83 mRNA instability element (HIE), which maps to a 615-nucleotide region of the open reading frame (ORF). The HIE is sufficient for association of a transgenic mRNA with SMG protein as well as for SMG-dependent destabilization. Although the Hsp83 mRNA is translated in the early embryo, we show that translation of the mRNA is not necessary for destabilization; indeed, the HIE functions even when located in an mRNA's 3' untranslated region. The Hsp83 mRNA contains eight predicted SMG recognition elements (SREs); all map to the ORF, and six reside within the HIE. Mutation of a single amino acid residue that is essential for SMG's interaction with SREs stabilizes endogenous Hsp83 transcripts. Furthermore, simultaneous mutation of all eight predicted SREs also results in transcript stabilization. A plausible model is that the multiple, widely distributed SREs in the ORF enable some SMG molecules to remain bound to the mRNA despite ribosome transit through any individual SRE. Thus, SMG can recruit the CCR4-NOT deadenylase to trigger Hsp83 mRNA degradation despite the fact that it is being translated. |
Databáze: | OpenAIRE |
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